Optimization Of Spectrum Extrapolation For Causal Impulse Response Calculation Using The Hilbert Transform

ABSTRACT

A causal impulse response function is calculated from a truncated spectrum by extending the real part of the spectrum beyond the truncation frequency and computing the imaginary part with the Hilbert transform to enforce causality. The out of band extrapolation is optimized to reduce the discrepancy between the computed and the original imaginary part in the in band frequency range so that the causal impulse response accurately represents the original spectrum. The technique can be applied to spectral with the delay phase subtracted to enforce delay causality. The Hilbert transform may be employed to maintain causality in S-parameter passivity violation correction. At frequencies where violation happens, the S-parameter matrix is scaled down by the inverse of the magnitude of the largest eigenvalue. Magnitudes at other frequencies are unchanged. An additional phase calculated by the magnitude phase Hilbert transform is added to the scaled spectrum to maintain the causality.

BACKGROUND

A linear component in a system is often represented in frequency domain. To obtain the time-domain response of the system driven by sources with given waveforms, the spectrum of the linear component must be converted to time-domain impulse response function by inverse Fourier transform. The Fourier transform involves integration of the spectrum over frequencies from DC to infinity. The spectral data is often available only up to the highest frequency of measurement or electromagnetic (EM) simulation. Even in cases where the analytic model of the spectrum is known, the numerical integration of the Fourier transform has to be truncated at a finite frequency. One consequence of spectrum truncation is the violation of causality in the impulse response, namely non-zero response at negative time. To restore causality, adjustments have to be made in the impulse response, including shifting the response toward the positive side of the time or manually removing responses at negative time. Such adjustments cause discrepancy between the impulse response and the original spectrum, and therefore inaccurate time-domain response. A common technique to deal with spectrum truncation is to apply a low-pass window to the spectrum. However, windowing does not solve and can worsen causality problem as it is equivalent to convolution of a low-pass filter with the original physical response. This operation always leads to ripples or ringing in negative time. Thus, it is hard to control the spectrum accuracy when adjusting the impulse response in the time domain.

While any physical response must be causal with respect to t=0, e.g. zero response when t<0, response of transmission lines must also be causal with respect to delay, e.g. zero response when t<delay time. The delay time is the time it takes for the signal travels from the input end to the output end. Delay causality should be enforced in the transmission line impulse response calculation from band-limited spectrum.

Another issue related to causality is the passivity correction of S-parameter data. Due to measurement noise or numerical error in EM simulation, S-parameter data of a passive component can be slightly non-passive at certain frequencies. Passivity violation could lead to unstable and erroneous waveforms. In time-domain simulation, it is required that the corrected S-parameters remain to be causal.

The simplest way to correct passivity violation is to scale the whole spectrum by a constant factor which is less than one. This method will not affect the causality of the spectrum. However, it penalizes the non-passive frequencies but also the passive ones. Therefore, the corrected spectrum is overly damped when compared to the original data.

SUMMARY

A causal impulse response function is calculated from a truncated spectrum by extending the real part of the spectrum beyond the truncation frequency and computing the imaginary part with the Hilbert transform to enforce causality. The out of band extrapolation is optimized to reduce the discrepancy between the computed and the original imaginary part in the in band frequency range so that the causal impulse response accurately represents the original spectrum.

For systems with delay, delay causality can be enforced in impulse response calculations by applying this technique to the modified spectrum which is shifted in time by the delay time.

The Hilbert transform may also be employed in passivity correction in S-parameter data to preserve the causal property of the response. Violation of passivity is corrected on frequency-by-frequency basis. At frequencies where violation happens, the s-parameter matrix is scaled down by the inverse of the magnitude of the largest eigenvalue. Magnitudes at other frequencies are unchanged. An additional phase calculated by the magnitude phase Hilbert transform is applied to maintain the causality of the scaled spectrum.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1 a and 1 b illustrates the real and imaginary parts of the spectral data according to the invention.

FIG. 2 is a process flowchart according to the invention.

FIGS. 3 a-c illustrate the impulse calculation in the prior art.

FIG. 4( a) illustrates the invention as applied to the same circuit used in FIGS. 4( a-c).

FIG. 5 shows the output waveforms of a micro-strip line with about 5.5 ns delay time.

FIG. 6( a) illustrates a s-parameter file for a circuit containing 200 identical elements. FIG. 6( b) shows that after the passivity correction as described above, the waveform is stabilized.

DETAILED DESCRIPTION

Applicant teaches enforcing causality directly in the frequency domain so the effects on the spectrum can be monitored. The spectrum causality condition is given by Kramers-Kronig relations that state that the real and imaginary parts of a causal response are related by the following Hilbert transforms:

$\begin{matrix} {{{u(\omega)} = {\frac{1}{}P{\int_{- \infty}^{\infty}{\frac{v\left( \omega^{\prime} \right)}{\omega - \omega^{\prime}}{\omega^{\prime}}}}}}{{v(\omega)} = {{- \frac{1}{\pi}}P{\int_{- \infty}^{\infty}{\frac{u\left( \omega^{\prime} \right)}{\omega - \omega^{\prime}}{\omega^{\prime}}}}}}} & {{Equation}\mspace{14mu} 1} \end{matrix}$

where u and v are real and imaginary parts of the spectrum respectively. P is the Cauchy principal value. For discrete samples, the Hilbert transform becomes:

$\begin{matrix} {{{u(\omega)} = {{h(0)} + {\frac{1}{2\pi}P{\int_{- \pi}^{\pi}{{v\left( \omega^{\prime} \right)}\cot \frac{\omega - \omega^{\prime}}{2}{\omega^{\prime}}}}}}}{{v(\omega)} = {{- \frac{1}{2\pi}}P{\int_{- \pi}^{\pi}{{u\left( \omega^{\prime} \right)}\cot \frac{\omega - \omega^{\prime}}{2}{\omega^{\prime}}}}}}} & {{Equation}\mspace{20mu} 2} \end{matrix}$

h(0) is the response at time equals zero. The Hilbert transform is used to enforce causality and minimize the discrepancy between the causal spectrum and the original spectrum within the in band frequency range by optimizing the out of band extrapolation.

As shown in FIG. 1, the real part u is extended continuously from the cut-off frequency f_max to the Nyquist frequency f_Nyqs using polynomial functions up to 4^(th) order.

u(f)=c0+c1·(f−f _(—) Nyqs)+c2·(f−f _(—) Nyqs)² +c3·(f−f _(—) Nyqs)³ +c4·(f−f _(—) Nyqs)⁴  Equation 3

Because spectrum of discrete samples replicates itself above the Nyquist frequency and because the real part of the spectrum of a real time-domain response is symmetric around zero frequency, u must be symmetric around f_Nyqs. Thus, odd order terms in equation 3 must be zero and

u(f)=c0+c2·(f−f _(—) Nyqs)² +c4·(f−f _(—) Nyqs)⁴  Equation 4

Coefficients c0, c2 and c4 in Equation 4 are determined by the value of u at f_Nyqs and by the continuation condition at f_max

$\begin{matrix} {\mspace{20mu} {{{u({f\_ Nyqs})} = {c\; 0}}{{u({f\_ max})} = {{c\; 0} + {c\; {2 \cdot \left( {{f\_ max} - {f\_ Nyqs}} \right)^{2}}} + {c\; {4 \cdot \left( {{f\_ max} - {f\_ Nyqs}} \right)^{4}}}}}{\frac{{u({f\_ max})}}{f} = {{{2 \cdot c}\; {0 \cdot \left( {{f\_ max} - {f\_ Nyqs}} \right)}} + {{4 \cdot c}\; {4 \cdot \left( {{f\_ max} - {f\_ Nyqs}} \right)^{3}}}}}}} & {{Equation}\mspace{14mu} 5} \end{matrix}$

As shown in equation 5, the extrapolation of u is determined by two variables, f_Nyqs and u(f_Nyqs).

The imaginary part v is calculated by the Hilbert transform of u to enforce causality and is compared with the original imaginary part from 0 to f_max. The discrepancy is minimized by optimizing values of f_Nyqs and u(f_Nyqs). The impulse response is then computed from the optimal causal spectrum u and v. The discrepancy in the imaginary part tends to be smaller at low frequency than at high frequency because of the convolution nature of the Hilbert transform.

FIG. 2 is a flowchart according to the invention. In step 100, different Nyquist frequencies are sampled. In step 102, different u(f_Nyqs) are sampled. In step 104, a Hilbert transform is performed on the real part to compute the imaginary. In step 106, the computed imaginary is compared to the original imaginary. In step 108, the optimal extrapolation curve is selected. In step 110, an inverse Fast Fourier Transform is performed for the impulse response.

FIG. 3( a) illustrates the conventional method for impulse response calculation, the response (dashed line) of a circuit represented by its s-parameter spectral up to 20 GHz failed to match the response (dotted line) of the same circuit represented by lumped elements. FIGS. 3( b) and 3(c) show the discrepancy in real and imaginary parts between the original spectrum (dotted line) and the spectrum corresponding to the impulse response (dashed line).

FIGS. 4( a-c) illustrates the invention as applied to the same circuit used in FIGS. 3( a-c). Perfect matching of the waveform was achieved between the s-parameter and the lumped element representations of the circuit.

The technique can be modified to enforce delay causality in transmission line impulse response calculations. The delay causal condition for impulse response h(t) is h(t)=0 when t<td, where td is the delay time. It is equivalent to condition h(t+td)=0 when t<0. The spectrum of h(t+td), H′(ω)), can be obtained from the spectrum of h(t), H(ω)), by subtracting the delay phase

H(ω)=exp(j·ω·t _(d))H(ω)  Equation 6

To enforce delay causality, first, the Hilbert transform based approach described above is applied on H′ so that H′ is causal with respect to t=0. After the causal h(t+td) is computed from H′, h(t) is obtained by shifting h(t+td) in time axis by td. The resulting h(t) is causal with respect to delay.

FIG. 5 shows the output waveforms of a micro-strip line with about 5.5 ns delay time. The result without delay causality enforcement (red line) shows non-causal response before the delay time. After the delay causality is applied, the result (blue line) has zero response before the delay time.

The Hilbert transform may be applied to restore causality in S-parameter data after correcting its passivity violation in a frequency-by-frequency basis. The passivity condition for s-parameter at a given frequency is that all the eigenvalues of the s-parameter matrix have magnitudes less than one. Due to measurement noise or numerical error in simulations, minor violations could occur in s-parameter data at certain frequencies.

The Applicants teach that the largest eigenvalue s_max is calculated at each frequency within the in band range. At the frequency where |s_max|>1, the s-parameter matrix is scaled down by factor 1/|s_maxl| to correct the passivity violation. Magnitudes at other frequencies including out of band region are unchanged. This approach has minimal impact on spectral accuracy and avoid over damping the original data. Since the magnitude of scaling is frequency dependent, an additional phase is added to the scaled spectrum to maintain causality. The phase is obtained by using the magnitude phase Hilbert transform:

${\varphi (\omega)} = {{- \frac{1}{2\pi}}P{\int_{- \pi}^{\pi}{\ln \; {\alpha \left( \omega^{\prime} \right)}\cot \frac{\omega - \omega^{\prime}}{2}{\omega^{\prime}}}}}$

α is the magnitude scaling factor and φ is the phase. For minor violations, α is very close to 1 and results in a small φ, typically of the order 1e-3. For passive frequencies, α is 1. The minimum phase condition is hence satisfied and causality of the combination of α and φ is guaranteed by the magnitude phase Hilbert transform.

FIG. 6( a) illustrates the simulated waveform of a circuit which contains 200 identical elements in cascade. Each element is represented by the same S-parameter data which is known to be non-passive. The passivity violation is amplified in the circuit by placing these elements in series and results in an unstable waveform. FIG. 6( b) shows that after the passivity correction as described above, the waveform is stabilized. 

1. A method comprising: selecting different Nyquist frequencies to be sampled; for each Nyquist frequency, sampling the extrapolation value of the S-parameter matrix; extrapolating the real part in the out-of-band region of the S-parameter matrix, performing a Hilbert transform on the extrapolated real part of the S-parameter matrix to compute the imaginary part of the S-parameter matrix, comparing the computed imaginary part to the imaginary part of a causal impulse response to obtain a difference signal, and selecting the Nyquist frequency and the extrapolation value as an optimal extrapolation curve when the difference signal is within a desired tolerance; and performing an inverse Fast Fourier Transform on the optimal extrapolation curve.
 2. A method, as in claim 1, comprising applying passivity correction of the causal impulse response.
 3. A method, as in claim 2, applying passivity correction comprising: scaling the S parameter matrix by 1/|s_max|; and adding phase according to Hilbert transform the scaled spectrum to maintain the causality.
 4. A method, as in claim 1, comprising enforcing delay causality.
 5. A method, as in claim 4, enforcing delay causality comprising: subtracting a delay phase factor of a predetermined delay time from the spectrum; performing optimization steps described in claim 1 to obtain a causal impulse response with respect to t=0; and shifting the causal impulse response by a predetermined amount. 